SU473956A1 - Peak voltmeter - Google Patents

Description

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The invention can be used in type 1 and selective pulse voltmeters, in particular, in radio interference meters and field strength meters.

The known peak voltmeters, containing an amplifier, a peak detector and an averaging indicator, are characterized by increased sensitivity to extraneous radio interference. Even rare, in fact single, imulse interfering signals due to a long constant discharge time can seriously distort the measurement results. Sometimes, to reduce the effects of interference, a special button is used to discharge the capacity of the detector load. In all cases, it is necessary to increase the measurement time in order to be able to verify the reliability of the measurement results.

Typically commercially available peak voltmeters are designed to measure detector-mined pulse sequences. Specific difficulties arise in measuring the peak level of random processes. In these cases, with a large measurement time, a release, in principle, with any amplitude within the amplitude-dynamic range of the circuit can always occur, albeit with a low probability. In these cases, the question remains with what probability the peak value of the random process is measured.

The aim of the invention is to reduce the influence of extraneous noise and to make it possible to measure the peak voltage level of random processes with a given probability.

This is achieved by introducing input and output key circuits, a bit circuit, a control oscillator into the proposed device, the input key circuit being turned on between the amplifier and the peak detector, parallel to the load of the peak detector 1 is connected to the controlled bit

a circuit, and between the peak detector and the averaging indicator, the output key circuit is turned on, with the control generator connected to the input and output key circuits.

The essence of the invention is that an automatic fixation of the peak level of the measured voltage for a certain adjustable time period is performed, followed by averaging. With increasing time intervals, the peak level of the random process will increasingly be measured.

Conversely, when the time intervals begin to decrease, the instantaneous values of the random values will be fixed in the limit.

process and after averaging its average value will be measured. With a decrease in time intervals, the effect of extraneous impulse noise also decreases, since they will be recorded only in separate time intervals and, naturally, have little effect on the total measured level after averaging.

FIG. 1 shows the block-to-diagram of the described voltmeter; in fig. 2-epiry napr.

The voltmeter is derived from amplifier 1, peak detector 2 and averaging indicator 3. Input key circuit 4 is turned on between the amplifier and the peak detector, and output key circuit 5 between the pzdkovy detector and averaging indicator 5. Both key circuits and discharge circuit 6 of the peak detector connected in parallel with its storage capacity, operate according to a program generated by the control generator 7.

The averaging indicator 3 is a detector circuit with equal constants of charge and discharge time, the output of which includes an indicator instrument calibrated by peak level. Key circuits 4 and 5 can be implemented in in; the idea of controlled diode switches or controlled cathode repeaters. The discharge circuit 6 is also a controlled diode switch. The control generator 7 consists of a master clock generator that starts the first standby multivibrator, which, with the falling edge of the rectangular pulse, triggers the second standby multivibrator.

The scheme works as follows. The C / 2-1 signal (in the plots of Fig. 2), the peak level of which is to be measured, is fed to the input of amplifier 1 and, after linear amplification, through the incoming key circuit 4, to the peak detector 2. The input key circuit is normally in the locked state and opens with C / 2-2 pulses at TI time from the first standby multivibrator of the control generator, the duration of which and the duration determine the gating characteristic

input signal. During this time, the cumulative capacitance of the peak detector 2 has time to charge up to the maximum level t / 2-4, which reaches the voltage t / 2-i 5 over a period of time n.

The back edges of the pulses f / 2-2 (after differentiation) start the second standby multivibrator of the control generator 7, which forms the 0 C / 2-h pulse sequence. These pulses are applied to the output key circuit 5, and their falling edge (after differentiation) instantly discharges the storage capacitance of the peak detector. Thus, at the output of the peak detector 2, t / 2-4 pulses are generated, and the averaging indicator 3 is pulsed (72-5 equal duration, the amplitudes of which are proportional to the maximum Q values, which the measured voltage reaches each time for gated intervals time n

Naturally, the averaging indicator 3 will record the average value of 5 peak level of the measured voltage during the time TI.

When measuring pulsed random processes, the whole scheme will work in a similar way, and

Subject invention

A peak voltmeter containing an amplifier, a peak detector and averaging mode, characterized in that, in order to reduce the effect of extraneous interference and to provide the ability to measure the peak voltage level with a predetermined probability, the input and output switches of the circuit are inserted, the discharge circuit , a control oscillator, with the input key circuit being switched on between the amplifier and the peak detector, a controllable bit is connected in parallel with the load of the peak detector

5, and an output key circuit is connected between the peak detector and the averaging indicator, the control generator being connected to the input and output key circuits.

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